The FANCD2-FANCI complex is recruited to DNA interstrand crosslinks before monoubiquitination of FANCD2

The Fanconi Anemia (FA) pathway is important for the repair of DNA interstrand crosslinks (ICL). The FANCD2-FANCI complex is central to the pathway, and localizes to ICLs dependent on its monoubiquitination. It has remained elusive whether the complex is recruited before or after the critical monoubiquitination. Here we report the first structural insight into the human FANCD2-FANCI complex by obtaining the cryo- EM structure. The complex contains an inner cavity, large enough to accommodate a double stranded DNA helix, as well as a protruding Tower domain. Disease-causing mutations in the Tower domain is observed in several FA patients. Our work reveals that recruitment of the complex to a stalled replication fork serves as the trigger for the activating monoubiquitination event. Taken together, our results uncover the mechanism of how the FANCD2-FANCI complex activates the FA pathway, and explains the underlying molecular defect in FA patients with mutations in the Tower domain

Annexin-A5 assembled into two-dimensional arrays promotes cell membrane repair

Eukaryotic cells possess a universal repair machinery that ensures rapid resealing of plasma membrane disruptions. Before resealing, the torn membrane is submitted to considerable tension, which functions to expand the disruption. Here we show that annexin-A5 (AnxA5), a protein that self-assembles into two-dimensional (2D) arrays on membranes upon Ca2+ activation, promotes membrane repair. Compared with wild-type mouse perivascular cells, AnxA5-null cells exhibit a severe membrane repair defect. Membrane repair in AnxA5-null cells is rescued by addition of AnxA5, which binds exclusively to disrupted membrane areas. In contrast, an AnxA5 mutant that lacks the ability of forming 2D arrays is unable to promote membrane repair. We propose that AnxA5 participates in a previously unrecognized step of the membrane repair process: triggered by the local influx of Ca2+, AnxA5 proteins bind to torn membrane edges and form a 2D array, which prevents wound expansion and promotes membrane resealing

Protein structure determination by electron cryo-microscopy.

Transmission electron cryo-microscopy (cryoEM) is a versatile tool in the structural analysis of proteins and biological macromolecular assemblies. In this review, we present a brief survey of the methods used in cryoEM, and their current developments. These latest advances provide exciting opportunities for the three-dimensional structural determination of macromolecular complexes that are either too large or too heterogeneous to be investigated by conventional X-ray crystallography or nuclear magnetic resonance (NMR). The endeavour of understanding the function of protein or macromolecular complex is often helped by combining data from electron microscopy and X-ray crystallography. We will thus provide a brief overview of the computational techniques involved in combining data from different techniques for the interpretation of the EM structure

Generation of protein lattices by fusing proteins with matching rotational symmetry

The self-assembly of supramolecular structures that are ordered on the nanometre scale is a key objective in nanotechnology. DNA 1-4 and peptide 5-7 nanotechnologies have produced various two- and three-dimensional structures, but protein molecules have been underexploited in this area of research. Here we show that the genetic fusion of subunits from protein assemblies that have matching rotational symmetry generates species that can self-assemble into well-ordered, pre-determined one- and two-dimensional arrays that are stabilized by extensive intermolecular interactions. This new class of supramolecular structure provides a way to manufacture biomaterials with diverse structural and functional properties. © 2011 Macmillan Publishers Limited. All rights reserved

The HupR receiver domain crystal structure in its nonphospho and inhibitory phospho states.

Hydrogen uptake protein regulator (HupR) is a member of the nitrogen regulatory protein C (NtrC) family of response regulators. These proteins activate transcription by RNA polymerase (RNAP) in response to a change in environment. This change is detected through the phosphorylation of their receiver domain as part of a two-component signalling pathway. HupR is an unusual member of this family as it activates transcription when unphosphorylated, and transcription is inhibited by phosphorylation. Also, HupR activates transcription through the more general sigma(70) transcription initiation factor, which does not require activation by ATPase, in contrast to other NtrC family members that utilise sigma(54). Hence, its mode of action is expected to be different from those of the more conventional NtrC family members. We have determined the structures of the unphosphorylated N-terminal receiver domain of wild-type HupR, the mutant HupR(D55E)(N) (which cannot be phosphorylated and down-regulated), and HupR in the presence of the phosphorylation mimic BeF(3)(-). The structures show a typical response regulator fold organised as a dimer whose interface involves alpha4-beta5-alpha5 elements. The interactions across the interface are slightly different between apo and phospho mimics, and these reflect a rearrangement of key conserved residues around the active site aspartate that have been implicated in domain activation in other receiver domain proteins. We also show that the wild-type HupR receiver domain forms a weak dimer in solution, which is strengthened in the presence of the phosphorylation mimic BeF(3)(-). The results indicate many features similar to those that have been observed in other systems, including NtrC (where phosphorylation is activatory), and indicate that recognition properties, which allow HupR to be active in the absence of phosphorylation, lie in the transmission of phosphorylation signals through the linker region to the other domains of the protein

Structural and functional studies of the response regulator HupR.

HupR is a response regulator that controls the synthesis of the membrane-bound [NiFe]hydrogenase of the photosynthetic bacterium Rhodobacter capsulatus. The protein belongs to the NtrC subfamily of response regulators and is the second protein of a two-component system. We have crystallized the full-length protein HupR in the unphosphorylated state in two dimensions using the lipid monolayer technique. The 3D structure of negatively stained HupR was calculated to a resolution of approximately 23 A from tilted electron microscope images. HupR crystallizes as a dimer, and forms an elongated V-shaped structure with extended arms. The dimensions of the dimer are about 80 A length, 40 A width and 85 A thick. The HupR monomer consists of three domains, N-terminal receiver domain, central domain and C-terminal DNA-binding domain. We have fitted the known 3D structure of the central domain from NtrC1 Aquifex aeolicus protein into our 3D model; we propose that contact between the dimers is through the central domain. The N-terminal domain is in contact with the lipid monolayer and is situated on the top of the V-shaped structure. The central domain alone has been expressed and purified; it forms a pentamer in solution and lacks ATPase activity

Projection structure of a transcriptional regulator, HupR, determined by electron cryo-microscopy.

Large, well-ordered two-dimensional crystals of the histidine-tagged-HupR protein, a transcriptional regulator from the photosynthetic bacterium Rhodobacter capsulatus, were obtained by specific interaction with a Ni(2+)-chelated lipid monolayer. HupR is a response regulator of the NtrC subfamily; it activates the transcription of the structural genes hupSLC, of [NiFe]hydrogenase. A projection map of the full-length protein at 9 A resolution was obtained by electron cryo-microscopy and image analysis of frozen-hydrated two-dimensional crystals. The crystals have a p6 plane group with unit cell dimensions of a=b=111.6(+/-1.0) A, gamma=120.4(+/-0.5) degrees. The structure of the N-terminal domain of NtrC, the family to which HupR belongs, had been determined previously by NMR. The atomic coordinates of the N-terminal domain of NtrC, were compared to the structure obtained by cryo-electron microscope techniques of the whole HupR. These results provide the first structure at medium resolution of a whole transcription factor, HupR from the NtrC family

Regulation of flagellum number by FliA and FlgM and role in biofilm formation by Rhodobacter sphaeroides.

The FlgM secretion checkpoint plays a crucial role in coordinating bacterial flagellar assembly. Here we identify a new role for FlgM and FliA as part of a complex regulatory network which controls flagellum number and is essential for efficient swimming and biofilm formation in the monotrichous bacterium Rhodobacter sphaeroides

Structural changes of the prion protein in lipid membranes leading to aggregation and fibrillization.

Prion diseases are associated with a major refolding event of the normal cellular prion protein, PrP(C), where the predominantly alpha-helical and random coil structure of PrP(C) is converted into a beta-sheet-rich aggregated form, PrP(Sc). Under normal physiological conditions PrP(C) is attached to the outer leaflet of the plasma membrane via a GPI anchor, and it is plausible that an interaction between PrP and lipid membranes could be involved in the conversion of PrP(C) into PrP(Sc). Recombinant PrP can be refolded into an alpha-helical structure, designated alpha-PrP isoform, or into beta-sheet-rich states, designated beta-PrP isoform. The current study investigates the binding of beta-PrP to model lipid membranes and compares the structural changes in alpha- and beta-PrP induced upon membrane binding. beta-PrP binds to negatively charged POPG membranes and to raft membranes composed of DPPC, cholesterol, and sphingomyelin. Binding of beta-PrP to raft membranes results in substantial unfolding of beta-PrP. This membrane-associated largely unfolded state of PrP is slowly converted into fibrils. In contrast, beta-PrP and alpha-PrP gain structure with POPG membranes, which instead leads to amorphous aggregates. Furthermore, binding of beta-PrP to POPG has a disruptive effect on the integrity of the lipid bilayer, leading to total release of vesicle contents, whereas raft vesicles are not destabilized upon binding of beta-PrP

Direct visualization of KirBac3.1 potassium channel gating by atomic force microscopy.

KirBac3.1 belongs to a family of transmembrane potassium (K(+)) channels that permit the selective flow of K-ions across biological membranes and thereby regulate cell excitability. They are crucial for a wide range of biological processes and mutations in their genes cause multiple human diseases. Opening and closing (gating) of Kir channels may occur spontaneously but is modulated by numerous intracellular ligands that bind to the channel itself. These include lipids (such as PIP(2)), G-proteins, nucleotides (such as ATP) and ions (e.g. H(+), Mg(2+), Ca(2+)). We have used high-resolution atomic force microscopy (AFM) to examine KirBac3.1 in two different configurations. AFM imaging of the cytoplasmic surface of KirBac3.1 embedded in a lipid bilayer has allowed visualization of the tetrameric assembly of the ligand-binding domain. In the absence of Mg(2+), the four subunits appeared as four protrusions surrounding a central depression corresponding to the cytoplasmic pore. They did not display 4-fold symmetry, but formed a dimer-of-dimers with 2-fold symmetry. Upon addition of Mg(2+), a marked rearrangement of the intracellular ligand-binding domains was observed: the four protrusions condensed into a single protrusion per tetramer, and there was an accompanying increase in protrusion height. The central cavity within the four intracellular domains also disappeared on addition of Mg(2+), indicating constriction of the cytoplasmic pore. These structural changes are likely transduced to the transmembrane helices, which gate the K(+) channel. This is the first time AFM has been used as an interactive tool to study K(+) channels. It has enabled us to directly measure the conformational changes in the protein surface produced by ligand binding